|Table of Contents|

Stiffness calculation of joint in steel truss-concrete composite girder(PDF)

长安大学学报(自然科学版)[ISSN:1006-6977/CN:61-1281/TN]

Issue:
2022年6期
Page:
121-132
Research Field:
桥梁工程·交通基础设施智能化运维技术专栏
Publishing date:

Info

Title:
Stiffness calculation of joint in steel truss-concrete composite girder
Author(s):
LU Ze-lei1 ZHANG Gang1 ZHOU Li1 MA Yan-yang2 WAN Hao1 WANG Shi-chao1
(1. School of Highway, Chang’an University, Xi’an 710064, Shaanxi, China; 2. China Railway Construction Shaanxi Expressway Co., Ltd, Xi’an 710064, Shaanxi, China)
Keywords:
bridge engineering steel truss-concrete composite girder numerical prediction truss-plate joint stiffness calculation method stability performance
PACS:
U441
DOI:
10.19721/j.cnki.1671-8879.2022.06.012
Abstract:
With the opportunity of construction and development of low-carbon and environment-friendly bridge steel truss-concrete composite girder, to further explore the stability of large gusset plate(truss-plate joint)in three-dimensional truss structure of steel truss-concrete composite girder and its influence on the overall structural performance. The refined solid model of the three-dimensional truss-plate joint and beam-solid composite structure were constructed, when considering the actual stiffness of welded joints. The moment-rotation curves of web member, chord and horizontal connection around strong axis and weak axis at the welded joint were calculated. Several sensitive parameters affecting the rotational stiffness of truss-plate joint were analyzed, and the variation laws of joint initial stiffness with the thickness of gusset plate, axial compression ratio and welding residual stress was revealed. The calculation method of truss-plate joint stiffness was established. On this basis, the change of joint rotational stiffness, which caused by joint plate thickness, axial compression ratio and welding thermal stress, and effects of joint rotational stiffness on the overall stability of steel truss-concrete composite girder were studied. Overall structure safety reserve of steel truss-concrete composite girder was obtained. The results show that the semi-rigid characteristics of steel truss welded joints are obvious. The formulas for the influence of truss-plate joint stiffness on the stability of overall structure were proposed. When the members rotate along the strong axis of the section, they have great strength and flexural stiffness, which in the weak axis are smaller. When the thickness of gusset plate increases from 20 to 40 mm, initial stiffness of truss-plate joint increases by 39.49%, ultimate rotation angle decreases by 46.40%, and the first-order buckling eigenvalue of the whole structure increases by 342.95%. When the axial compression ratio increases from 0 to 0.8, initial stiffness of truss-plate joint decreases by 12.20%, ultimate rotation angle decreases by 24.43%, and the first-order buckling eigenvalue of the whole structure decreases by 55.48%. Considering the welding residual stress, initial stiffness of truss-plate joint decreases by 8.63%, ultimate rotation angle decreases by 26.01%, and the first-order buckling eigenvalue of the whole structure decreases by 4.90%. The proposed formulas are simple and practical, the research results will provide theoretical basis for the whole life design and construction of steel truss-concrete composite continuous girder.4 tabs, 11 figs, 34 refs.

References:

[1] 卫 星,肖 林,温宗意,等.钢混组合结构桥梁2020年度研究进展[J].土木与环境工程学报(中英文),2021,43(增1):107-119.
WEI Xing,XIAO Lin,WEN Zong-yi,et al.State-of-the-art review of steel-concrete composite bridges in 2020[J].Journal of Civil and Environmental Engineering,2021,43(S1):107-119.
[2]赵均海,樊军超,胡 壹,等.复式钢管混凝土结构研究现状与发展趋[J].长安大学学报(自然科学版),2022,42(1):1-15.
ZHAO Jun-hai,FAN Jun-chao,HU Yi,et al.Research status and development trend of concrete-filleddouble steel tube structures[J].Journal of Chang’an University(Natural Science Edition),2022,42(1):1-15.
[3]张冬芳,赵均海,贺拴海,等.复式钢管混凝土柱-钢梁节点应力分布与传力机制研究[J].建筑结构,2018,48(15):37-43.
ZHANG Dong-fang,ZHAO Jun-hai,HE Shuan-hai,et al.Stress distribution and force-transferring mechanism of connections between concrete-filled double steel tubular column and steel beam[J].Building Structure,2018,48(15):37-43.
[4]周 历.钢桁-混凝土组合连续梁复杂节点域刚度计算及稳定性能研究[D].西安:长安大学,2021.
ZHOU Li.Method of complex joint region in steel truss-concrete composite continuous bridge girders calculation and stability[D].Xi’an:Chang’an University,2021.
[5]康子恒,王森林,杜喜凯,等.T形钢连接半刚性梁柱节点受力性能研究[J].建筑结构学报,2020,41(增1):44-54.
KANG Zi-heng,WANG Sen-lin,DU Xi-kai,et al.Study on mechanical behavior of semi-rigid beam-column joints with T-section connections[J].Journal of Building Structures,2020,41(S1):44-54.
[6]石文龙,叶志明,李国强.半刚性连接框架的试验研究进展(Ⅱ)[J].四川建筑科学研究,2008,34(3):1-4.
SHI Wen-long,YE Zhi-ming,LI Guo-qiang.Development in experimental research on semi-rigid connection frames(Ⅱ)[J].Sichuan Building Science,2008,34(3):1-4.
[7]GB 50017—2017,钢结构设计标准[S].
GB 50017—2017,Standard for design of steel structures[S].
[8]GARDNER L,NETHERCOT D.Designers’ guide to EN 1993-1-1 Eurocode 3:Design of steel structures——General rules and rules for buildings[M].Brussels:Thomas Telford Ltd,2005.
[9]CHENAGHLOU M R,NOOSHIN H,HARDING J E.Proposed mathematical model for semi-rigid joint behaviour(M-θ)in space structures[J].International Journal of Space Structures,2014,29(2):71-80.
[10]CHENAGHLOU M R,NOOSHIN H.Axial force-bending moment interaction in a jointing system part Ⅰ:Experimental study[J].Journal of Constructional Steel Research,2015,113:261-276.
[11]SIEKIERSKI W.Analysis of gusset plate of contemporary bridge truss girder[J].The Baltic Journal of Road and Bridge Engineering,2016,11(3):188-196.
[12]CROSTI C,DUTHINH D.A nonlinear model for gusset plate connections[J].Engineering Structures,2014,62/63:135-147.
[13]CROSTI C,DUTHINH D.Instability of steel gusset plates in compression[J].Structure and Infrastructure Engineering,2014,10(8):1038-1048.
[14]何东升,郑清刚,徐 伟.板桁组合结构主桁节点板应力集中系数研究[J].桥梁建设,2020,50(3):46-51.
HE Dong-sheng,ZHENG Qing-gang,XU Wei.Study of stress concentration factor for main truss gusset plates in plate-truss composite structure[J].Bridge Construction,2020,50(3):46-51.
[15]尹国安,王海波.一种钢-混组合桁架桥下弦杆节点极限承载力研究[J].土木工程学报,2016,49(4):88-95.
YIN Guo-an,WANG Hai-bo.Study on ultimate bearing capacity of steel-concrete composite truss bridge bottom-chord joints[J].China Civil Engineering Journal,2016,49(4):88-95.
[16]门进杰,王家琛,樊冠磊,等.RCS梁柱节点半刚性连接弯矩-转角关系模型研究[J].土木工程学报,2020,53(10):36-50.
MEN Jin-jie,WANG Jia-chen,FAN Guan-lei,et al.Moment-rotation model of semi-rigid connection of RCS beam-column assembly[J].China Civil Engineering Journal,2020,53(10):36-50.
[17]牟在根,杨雨青,苏雪楠,等.端板连接半刚性钢管柱-单轴对称梁的弯矩-转角曲线计算方法[J].天津大学学报(自然科学与工程技术版),2018,51(增1):57-64.
MU Zai-gen,YANG Yu-qing,SU Xue-nan,et al.Moment-rotation curve calculation method for the semi-rigid end-plate connection of steel tube columns with uniaxial symmetry beam[J].Journal of Tianjin University(Science and Technology),2018,51(S1):57-64.
[18]SHON S D,HWANG K J,LEE S J.Numerical evaluation of buckling behavior in space structure considering geometrical parameters with joint rigidity[J].Journal of Central South University,2014,21(3):1115-1124.
[19]MOHAMMED D R,ISMAEL M A.Effect of semi-rigid connection on post-buckling behaviour of frames using finite element method[J].Civil Engineering Journal-Tehran,2019,5(7):1619-1630.
[20]高 强,黄天立,陈 龙,等.整体节点刚度对钢桁梁桥受力性能的影响[J].土木工程与管理学报,2019,36(5):144-149,156.
GAO Qiang,HUANG Tian-li,CHEN Long,et al.Influence of stiffness of integral joints on mechanical properties of steel truss girder bridges[J].Journal of Civil Engineering and Management,2019,36(5):144-149,156.
[21]盛兴旺,郑纬奇,戴 劲.考虑整体节点刚域模拟影响的钢桁梁力学效应分析[J].桥梁建设,2016,46(6):78-82.
SHENG Xing-wang,ZHENG Wei-qi,DAI Jin.Analysis of mechanical effect of steel truss girder considering influences of rigid zone simulation of integral joints[J].Bridge Construction,2016,46(6):78-82.
[22]周凌宇,薛宪鑫,李龙祥,等.考虑节点刚度的钢桁腹连续箱梁桥多尺度分析[J].铁道科学与工程学报,2018,15(11):2851-2860.
ZHOU Ling-yu,XUE Xian-xin,LI Long-xiang,et al.Multi-scale analysis of continuous box girder bridge with steel truss webs considering the joint stiffness[J].Journal of Railway Science and Engineering,2018,15(11):2851-2860.
[23]周凌宇,薛宪鑫.外接式组合桁架节点初始转动刚度研究[J].工程力学,2019,36(5):100-109.
ZHOU Ling-yu,XUE Xian-xin.Study on initial rotational stiffness of external composite truss joint[J].Engineering Mechanics,2019,36(5):100-109.
[24]HAN Q H,LIU Y M,XU Y.Stiffness characteristics of joints and influence on the stability of single-layer latticed domes[J].Thin-Walled Structures,2016,107:514-525.
[25]李 峰,娄巧娜.节点轴向刚度对圆柱面巨型网格结构静力性能的影响研究[J].建筑科学,2015,31(1):99-103.
LI Feng,LOU Qiao-na.Static performance research on cylindrical reticulated mega-structure with semi-rigid joints[J].Building Science,2015,31(1):99-103.
[26]李 峰,娄巧娜,刘 涛,等.基于节点刚度的柱面巨型网格结构静力性能研究[J].西安建筑科技大学学报(自然科学版),2014,46(5):682-686.
LI Feng,LOU Qiao-na,LIU Tao,et al.Static performance research on cylindrical reticulated mega-structure based on joints stiffness[J].Journal of Xi’an University of Architecture & Technology(Natural Science Edition),2014,46(5):682-686.
[27]舒赣平,刘 伟,陈绍礼.半刚性钢框架的直接分析方法理论研究[J].建筑结构学报,2014,35(8):142-150.
SHU Gan-ping,LIU Wei,CHEN Shao-li.Theoretical research on direct analysis method for semi-rigid steel frames[J].Journal of Building Structures,2014,35(8):142-150.
[28]JGJ 99—2015,高层民用建筑钢结构技术规程[S].
JGJ 99—2015,Technical specification for steel structure of tall building[S].
[29]班慧勇,施 刚,石永久,等.Q460高强钢焊接箱形截面残余应力研究[J].建筑结构学报,2013,34(1):14-21.
BAN Hui-yong,SHI Gang,SHI Yong-jiu,et al.Investigation on residual stress in Q460 high strength steel welded box sections[J].Journal of Building Structures,2013,34(1):14-21.
[30]张 岗,贺拴海,宋超杰,等.钢结构桥梁抗火研究综述[J].中国公路学报,2021,34(1):1-11.
ZHANG Gang,HE Shuan-hai,SONG Chao-jie,et al.Review on fire resistance of steel structural bridge girders[J].China Journal of Highway and Transport,2021,34(1):1-11.
[31]张 岗,宋超杰,李徐阳,等.燃油火灾下预应力混凝土梁耐火试验[J].中国公路学报,2022,35(1):210-221.
ZHANG Gang,SONG Chao-jie,LI Xu-yang,et al.Experimental study on fire resistance of prestressed concrete girders under fuel fire exposure[J].China Journal of Highway and Transport,2022,35(1):210-221.
[32]ZHANG G,KODUR V,SONG C J,et al.A numerical model for evaluating fire performance of composite box bridge girders[J].Journal of Constructional Steel Research,2020,165:105823.
[33]SONG C J,ZHANG G,LI X Y,et al.Experimental and numerical study on failure mechanism of steel-concrete composite bridge girders under fuel fire exposure[J].Engineering Structure,2021,247:113230.
[34]张 岗,汤陈皓,宋超杰,等.钢桁-混凝土组合结构桥梁耐火性能研究[J/OL].建筑结构学报,[2022-12-23].https://doi.org/10.14006/j.jzjgxb.2022.0260.
ZHANG Gang,TANG Chen-hao,SONG Chao-jie,et al.Fire resistance of steel truss-concrete composite bridge girde[J].Journal of Building Structures,[2022-12-23].https://doi.org/10.14006/j.jzjgxb.2022.0260.

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Last Update: 2022-12-20